Update parser to match * and & spec change.
The * and & operator grammar was updated in the spec to closer match other languages. This CL updates the Tint WGSL parser to match the current spec. Bug: tint:1756 Change-Id: I81b7c373bbd6a540b9273813c63a29487e2907ce Reviewed-on: https://dawn-review.googlesource.com/c/dawn/+/111580 Kokoro: Kokoro <noreply+kokoro@google.com> Commit-Queue: Dan Sinclair <dsinclair@chromium.org> Reviewed-by: Ben Clayton <bclayton@google.com>
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@ -3227,47 +3227,46 @@ Maybe<const ast::Expression*> ParserImpl::core_lhs_expression() {
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}
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}
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// lhs_expression
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// lhs_expression
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// : ( STAR | AND )* core_lhs_expression component_or_swizzle_specifier?
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// : core_lhs_expression component_or_swizzle_specifier ?
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// | AND lhs_expression
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// | STAR lhs_expression
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Maybe<const ast::Expression*> ParserImpl::lhs_expression() {
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Maybe<const ast::Expression*> ParserImpl::lhs_expression() {
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std::vector<const Token*> prefixes;
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while (peek_is(Token::Type::kStar) || peek_is(Token::Type::kAnd) ||
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peek_is(Token::Type::kAndAnd)) {
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auto& t = next();
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// If an '&&' is provided split into '&' and '&'
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if (t.Is(Token::Type::kAndAnd)) {
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split_token(Token::Type::kAnd, Token::Type::kAnd);
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}
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prefixes.push_back(&t);
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}
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auto core_expr = core_lhs_expression();
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auto core_expr = core_lhs_expression();
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if (core_expr.errored) {
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if (core_expr.errored) {
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return Failure::kErrored;
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return Failure::kErrored;
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} else if (!core_expr.matched) {
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}
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if (prefixes.empty()) {
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if (core_expr.matched) {
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return Failure::kNoMatch;
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return component_or_swizzle_specifier(core_expr.value);
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}
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}
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return add_error(peek(), "missing expression");
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auto check_lhs = [&](ast::UnaryOp op) -> Maybe<const ast::Expression*> {
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}
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auto& t = peek();
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auto expr = lhs_expression();
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const auto* expr = core_expr.value;
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if (expr.errored) {
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for (auto it = prefixes.rbegin(); it != prefixes.rend(); ++it) {
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auto& t = **it;
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ast::UnaryOp op = ast::UnaryOp::kAddressOf;
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if (t.Is(Token::Type::kStar)) {
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op = ast::UnaryOp::kIndirection;
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}
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expr = create<ast::UnaryOpExpression>(t.source(), op, expr);
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}
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auto e = component_or_swizzle_specifier(expr);
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if (e.errored) {
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return Failure::kErrored;
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return Failure::kErrored;
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}
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}
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return e.value;
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if (!expr.matched) {
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return add_error(t, "missing expression");
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}
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return create<ast::UnaryOpExpression>(t.source(), op, expr.value);
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};
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// If an `&&` is encountered, split it into two `&`'s
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if (match(Token::Type::kAndAnd)) {
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// The first `&` is consumed as part of the `&&`, so this needs to run the check itself.
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split_token(Token::Type::kAnd, Token::Type::kAnd);
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return check_lhs(ast::UnaryOp::kAddressOf);
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}
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if (match(Token::Type::kAnd)) {
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return check_lhs(ast::UnaryOp::kAddressOf);
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}
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if (match(Token::Type::kStar)) {
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return check_lhs(ast::UnaryOp::kIndirection);
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}
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return Failure::kNoMatch;
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}
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}
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// variable_updating_statement
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// variable_updating_statement
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@ -100,6 +100,31 @@ TEST_F(ParserImplTest, LHSExpression_Multiple) {
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EXPECT_TRUE(expr->Is<ast::IdentifierExpression>());
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EXPECT_TRUE(expr->Is<ast::IdentifierExpression>());
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}
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}
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TEST_F(ParserImplTest, LHSExpression_PostfixExpression_Array) {
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auto p = parser("*a[0]");
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auto e = p->lhs_expression();
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ASSERT_FALSE(p->has_error()) << p->error();
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ASSERT_FALSE(e.errored);
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EXPECT_TRUE(e.matched);
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ASSERT_NE(e.value, nullptr);
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ASSERT_TRUE(e->Is<ast::UnaryOpExpression>());
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auto* u = e->As<ast::UnaryOpExpression>();
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EXPECT_EQ(u->op, ast::UnaryOp::kIndirection);
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ASSERT_TRUE(u->expr->Is<ast::IndexAccessorExpression>());
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auto* access = u->expr->As<ast::IndexAccessorExpression>();
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ASSERT_TRUE(access->object->Is<ast::IdentifierExpression>());
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auto* obj = access->object->As<ast::IdentifierExpression>();
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EXPECT_EQ(obj->symbol, p->builder().Symbols().Get("a"));
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ASSERT_TRUE(access->index->Is<ast::IntLiteralExpression>());
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auto* idx = access->index->As<ast::IntLiteralExpression>();
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EXPECT_EQ(0, idx->value);
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}
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TEST_F(ParserImplTest, LHSExpression_PostfixExpression) {
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TEST_F(ParserImplTest, LHSExpression_PostfixExpression) {
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auto p = parser("*a.foo");
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auto p = parser("*a.foo");
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auto e = p->lhs_expression();
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auto e = p->lhs_expression();
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@ -107,16 +132,17 @@ TEST_F(ParserImplTest, LHSExpression_PostfixExpression) {
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ASSERT_FALSE(e.errored);
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ASSERT_FALSE(e.errored);
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EXPECT_TRUE(e.matched);
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EXPECT_TRUE(e.matched);
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ASSERT_NE(e.value, nullptr);
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ASSERT_NE(e.value, nullptr);
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ASSERT_TRUE(e->Is<ast::MemberAccessorExpression>());
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ASSERT_TRUE(e->Is<ast::UnaryOpExpression>());
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auto* access = e->As<ast::MemberAccessorExpression>();
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auto* u = e->As<ast::UnaryOpExpression>();
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ASSERT_TRUE(access->structure->Is<ast::UnaryOpExpression>());
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auto* u = access->structure->As<ast::UnaryOpExpression>();
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EXPECT_EQ(u->op, ast::UnaryOp::kIndirection);
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EXPECT_EQ(u->op, ast::UnaryOp::kIndirection);
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ASSERT_TRUE(u->expr->Is<ast::IdentifierExpression>());
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ASSERT_TRUE(u->expr->Is<ast::MemberAccessorExpression>());
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auto* struct_ident = u->expr->As<ast::IdentifierExpression>();
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auto* access = u->expr->As<ast::MemberAccessorExpression>();
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ASSERT_TRUE(access->structure->Is<ast::IdentifierExpression>());
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auto* struct_ident = access->structure->As<ast::IdentifierExpression>();
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EXPECT_EQ(struct_ident->symbol, p->builder().Symbols().Get("a"));
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EXPECT_EQ(struct_ident->symbol, p->builder().Symbols().Get("a"));
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ASSERT_TRUE(access->member->Is<ast::IdentifierExpression>());
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ASSERT_TRUE(access->member->Is<ast::IdentifierExpression>());
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@ -1298,6 +1298,23 @@ TEST_F(ResolverTest, U32_Overflow) {
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EXPECT_EQ(r()->error(), "12:24 error: value 4294967296 cannot be represented as 'u32'");
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EXPECT_EQ(r()->error(), "12:24 error: value 4294967296 cannot be represented as 'u32'");
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}
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}
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// var a: array<i32,2>;
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// *&a[0] = 1;
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TEST_F(ResolverTest, PointerIndexing_Fail) {
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// var a: array<i32,2>;
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// let p = &a;
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// *p[0] = 0;
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auto* a = Var("a", ty.array<i32, 2>());
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auto* p = AddressOf("a");
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auto* idx = Assign(Deref(IndexAccessor(p, 0_u)), 0_u);
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WrapInFunction(a, idx);
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EXPECT_FALSE(r()->Resolve());
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EXPECT_EQ(r()->error(), "error: cannot index type 'ptr<function, array<i32, 2>, read_write>'");
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}
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} // namespace
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} // namespace
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} // namespace tint::resolver
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} // namespace tint::resolver
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